Pichler, ThomasThomasPichler2024-08-272024-08-272005-011432-0495https://media.suub.uni-bremen.de/handle/elib/823010.26092/elib/3264The application of sulfur isotope (δ34S) values of sulfate in groundwater provided the information necessary to evaluate the source, transport and fate of battery acid and associated contaminants at the Gulf Coast Recycling (GCR) facility. The chemical and isotopic composition of groundwater beneath the (GCR) property, a battery recycling facility in east Tampa, Florida, varies more than expected for an area of comparable size. Sulfate (SO42−) values, for example, range from 1.2 to 11,500 mg/L and oxygen and hydrogen isotopes do not attenuate towards the weighted annual mean. Those samples that are high in sulfate generally have a low pH, which immediately indicates battery acid (H2SO4) contamination as a potential source for the sulfate. The low pH and high reactivity of the sulfuric acid groundwater cause the formation of hydrogeological microenvironments due to preferential dissolution of carbonate minerals, which in turn causes enhanced recharge and groundwater flow in certain areas; thus, the extreme scatter in the data set. Because of the difficult hydrogeology it is not straightforward to delineate the point-sources of contamination and up to five potential scenarios have to be evaluated: (1) seawater intrusion, (2) upwelling of high-sulfate groundwater, (3) local dissolution of gypsum, (4) an up-gradient contaminant source to the northeast of the GCR property and (5) battery acid contamination.enAlle Rechte vorbehaltenAlle Rechte vorbehaltenTracersisotopeSulfurGroundwater contaminationδ34SFloridaUSA500 Naturwissenschaften und Mathematik::550 Geowissenschaften, GeologieArtikel/Aufsatzurn:nbn:de:gbv:46-elib82305